User Equipment, Network Node and Methods Therein for Handling Preamble Transmissions on a Random Access Channel in a Radio Communications Network

ABSTRACT

The embodiments herein relate to a user equipment ( 121 ) and a method performed by the UE ( 121 ) for performing preamble transmissions, on a random access channel, to a network node ( 110 ). The method comprising: determining ( 801 ) a starting subframe for the preamble transmissions based on at least a system frame number (SFN), a number of times (R) the preamble transmissions is to be repeated and a random access channel configuration, and transmitting ( 802 ), to the network node ( 121 ) the preamble repeatedly starting in the determined starting subframe. The embodiments herein also relate to a network node ( 110 ) and a method performed by the network node ( 110 ).

TECHNICAL FIELD

Embodiments herein relate to transmissions on a random access channel ina radio communication network. In particular, embodiments herein relateto a user equipment and a method therein for performing preambletransmissions on the random access channel, to a network node.Embodiments also relate to a network node and a method therein forreception of preamble transmissions from the user equipment.

BACKGROUND

In a typical radio communications network, wireless terminals, alsoknown as mobile stations, terminals and/or user equipments (UEs)communicate via a Radio Access Network (RAN) to one or more corenetworks. The radio access network covers a geographical area which isdivided into cell areas, with each cell area being served by a basestation, e.g. a radio base station (RBS) or network node, which in somenetworks may also be called, for example, a “NodeB” or “eNodeB”. A cellis a geographical area where radio coverage is provided by the radiobase station at a base station site or an antenna site in case theantenna and the radio base station are not collocated. Each cell isidentified by an identity within the local radio area, which isbroadcasted in the cell. Another identity identifying the cell uniquelyin the whole mobile network is also broadcasted in the cell. One basestation may have one or more cells. A cell may be downlink and/or uplinkcell. The base stations communicate over the air interface operating onradio frequencies with the user equipments within range of the basestations.

A Universal Mobile Telecommunications System (UMTS) is a thirdgeneration mobile communication system, which evolved from the secondgeneration (2G) Global System for Mobile Communications, (GSM). The UMTSterrestrial radio access network, (UTRAN), is essentially a RAN usingwideband code division multiple access (WCDMA9 and/or High Speed PacketAccess (HSPA) for user equipments. In a forum known as the ThirdGeneration Partnership Project (3GPP) telecommunications supplierspropose and agree upon standards for third generation networks and UTRANspecifically, and investigate enhanced data rate and radio capacity. Insome versions of the RAN as e.g. in UMTS, several base stations may beconnected, e.g., by landlines or microwave, to a controller node, suchas a radio network controller (RNC) or a base station controller (BSC)which supervises and coordinates various activities of the plural basestations connected thereto. The RNCs are typically connected to one ormore core networks.

Specifications for the Evolved Packet System (EPS) have been completedwithin 3GPP, and this work continues in the coming 3GPP releases. TheEPS comprises the Evolved Universal Terrestrial Radio Access Network(E-UTRAN) also known as the Long Term Evolution, LTE, radio access, andthe Evolved Packet Core (EPC) also known as System ArchitectureEvolution (SAE) core network. E-UTRAN/LTE is a variant of a 3GPP radioaccess technology wherein the radio base station nodes are directlyconnected to the EPC core network rather than to RNCs. In general, inE-UTRAN/LTE the functions of a RNC are distributed between the radiobase stations nodes, e.g. eNodeBs in LTE, and the core network. As such,the RAN, of an EPS has an essentially “flat” architecture comprisingradio base station nodes without reporting to RNCs.

RANDOM ACCESS

In LTE, as in any communication system, a UE may need to contact oraccess the radio communications network, i.e. via the base station,without having a dedicated resource in the uplink or UL, i.e. from UE tobase station. To handle this, a random access procedure is availablewhere a UE that does not have a dedicated UL resource may transmit asignal to the base station. The first message of this procedure istypically transmitted on a special resource reserved for random access,a physical random access channel. This random access channel may forexample be limited in time and/or frequency, e.g. as in LTE. FIG. 1 isan illustration of an example of a random-access-preamble transmission.Uplink resources used for data transmission are shown as well as uplinkresource reserved for random access preamble transmission. Such anuplink resource may comprise 6 resource blocks (RBs) and is 1 ms longcorresponding to one subframe. A frame in LTE is comprised of 10subframes.

In LTE, the UE first detects a cell by using primary and secondarysynchronization signals. The UE blindly searches for a number ofdifferent sequences and the detected sequences give a physical cell ID(PCI). After detecting the cell, the UE reads the master informationblock (MIB) on the physical broadcast channel (PBCH) occupying a knownresource. The MIB gives the UE information about the system frame number(SFN) and how to detect further system information. More detailed systeminformation is then provided in a number of system information blocks(SIBs). The first SIB, denoted SIB1, comprises the cell identity andscheduling information on how to decode the following SIBs.

Information about the resources available for the physical random accesschannel (PRACH) transmission is provided to the UEs as part of thebroadcasted system information in System Information Block 2 (SIB2) oras part of dedicated radio resource control (RRC) signaling in case ofe.g. a handover. The resources comprise a preamble sequence and atime/frequency resource. In each cell, there are 64 preamble sequencesavailable. Two subsets of the 64 sequences are defined, where the set ofsequences in each subset is signaled as part of the system information.The time/frequency resources are also associated to a temporaryidentifier denoted random access radio network temporary identifier(RA-RNTI). The RA-RNTI is according to Eq. 1:

RA-RNTI=1+t _(—) id+10*f _(—) id   (Eq. 1)

-   -   where    -   t_id is the index of the first subframe of the specified PRACH,        0≦t_id <10; and    -   f_id is the index of the specified PRACH within that subframe,        in ascending order of frequency domain, 0≦f_id<6.

According to the 3GPP technical specifications 3GPP TS 36.211, themultiple random access preambles are generated from one or severalZadoff-Chu sequences. The set of 64 preamble sequences in a cell isfound by including the available cyclic shifts from each Zadoff-Chusequence and adding more Zadoff-Chu sequences as needed. The number ofcyclic shifts in a Zadoff-Chu sequence depends on N_(cs) given by thezero correlation zone configuration and whether unrestricted orrestricted sets of cyclic shifts are used. The sequences to use and thenumber of cyclic shifts to use per sequence are signaled in the systeminformation.

When performing a (contention-based) random-access attempt, the UEselects at random one sequence in one of the subsets. As long as noother UE is performing a random-access attempt using the same sequenceat the same time instant, no collisions will occur and the attempt will,with a high likelihood, be detected by the base station.

In LTE, the random access procedure may be used for a number ofdifferent reasons. Among these reasons are: initial access, i.e. for UEsin the RRC_IDLE state; incoming handover; resynchronization of the UL;scheduling request, i.e. for a UE that is not allocated any otherresource for contacting the base station; and positioning.

The contention-based random access procedure used in release 10 of LTE(LTE Rel-10) is illustrated in FIG. 2 depicting signalling over the airinterface between the UE and the LTE radio access network node (RANnode) e.g. a eNB or eNodeB.

As previously described, the system information including sequences forrandom access is signaled to the UE.

As shown in FIG. 2, the UE starts the random access procedure byrandomly selecting one of the preambles available for contention-basedrandom access.

The UE then transmits the selected random access preamble on the PRACHto the base station or LTE RAN node.

The LTE RAN base station acknowledges any preamble it detects bytransmitting a random access response message (MSG2), including aninitial grant to be used on the uplink shared channel, a temporarycell-RNTI (TC-RNTI) and a time alignment (TA) update based on the timingoffset of the preamble measured by the base station (or LTE RAN node) onthe PRACH. The MSG2 is transmitted in the downlink (DL) to the UE usingthe physical downlink shared channel (PDSCH) and its correspondingphysical downlink control channel (PDCCH) message that schedules thePDSCH comprises a cyclic redundancy check (CRC) which is scrambled withthe RA-RNTI.

When receiving the response, the UE uses the grant to transmit a message(MSG3), denoted scheduled transmission that in part is used to triggerthe establishment of radio resource control and in part to uniquelyidentify the UE on the common channels of the cell. The timing alignmentcommand provided in the random access response is applied in the ULtransmission in MSG3.

In addition, the eNB (or LTE RAN node) may also change the resourcesblocks that are assigned for a MSG3 transmission by sending an UL grantthat has its CRC scrambled with the TC-RNTI which was included in MSG2.In this case the PDCCH is used to transmit the downlink controlinformation (DCI) comprising the uplink grant.

The MSG4 which is then contention resolving has its PDCCH CRC scrambledwith the C-RNTI if the UE previously has a C-RNTI assigned. If the UEdoes not have a C-RNTI previously assigned the PDCCH CRC is scrambledwith the TC-RNTI obtained from MSG2. In the first case the UE includedC-RNTI into MSG3 whereas in the latter case the UE included a corenetwork identifier.

The procedure ends with RAN solving any preamble contention that mayhave occurred for the case that multiple UEs transmitted the samepreamble at the same time. This may occur since each UE randomly selectswhen to transmit and which preamble to use. If multiple UEs select thesame preamble for the transmission on RACH, there will be contentionbetween these UEs that needs to be resolved through the contentionresolution message, MSG4. Hybrid automatic repeat request (HARQ)acknowledgment (ACK) messages are also shown transmitted from the UErespectively the LTE RAN node. The case when contention occurs isillustrated in FIG. 3 below.

FIG. 3 illustrates an example of contention-based random access, wherethere is contention between two UEs, UE₁ and UE₂, i.e. where two UEstransmit the same preamble, p₅, at the same time. A third UE, UE₃, alsotransmits on the same RACH, but since it transmits with a differentpreamble, there is no contention between this UE and the other two UEs.

A UE may also perform non-contention-based random access. Anon-contention-based random access or contention-free random access maye.g. be initiated by the base station or eNB, to get the UE to achievesynchronisation in UL. The base station initiates a non-contention-basedrandom access either by sending a PDCCH order or indicating it in an RRCmessage. The later of the two is used in case of handover to anothercell. The eNB may also order the UE through a PDCCH message to perform acontention-based random access.

The procedure for the UE to perform contention-free random access isillustrated in FIG. 4. FIG. 4 illustrates an example of signalling overthe air interface for the contention-free random access procedure inLTE.

Similar to the contention-based random access the MSG2 is transmitted inthe DL to the UE and its corresponding PDCCH message CRC is scrambledwith the RA-RNTI. The UE considers the contention resolutionsuccessfully completed after it has received MSG2 successfully. Therandom access (RA) order is shown transmitted from the LTE RAN node tothe UE. The UE responds by transmitting a random access preamble to theLTE RAN node.

For the contention-free random access as for the contention-based randomaccess, MSG2 comprises a timing alignment (TA) value. This enables thebase station to set the initial/updated timing according to the UEstransmitted preamble.

It should be mentioned that a UE monitors the physical downlink controlchannel (PDCCH). In detail, a UE monitors a common search space and a UEspecific search 10 space in the PDCCH. In each search space, a limitednumber of candidates or equivalently PDCCH transmission hypothesis ischecked, in every DL subframe. These are known as blind decodes, and theUE checks whether any of the transmitted DCI messages is intended forit. The UE monitors the following RNTI that are associated with therandom access and paging procedures for each associated search spaces onPDCCH:

-   -   the RA-RNTI for MSG2 is monitored in the common search space.    -   the TC-RNTI for MSG3 is monitored in the common search space,        for reallocating the MSG3 in frequency.    -   the TC-RNTI for MSG4 is monitored in the common search and UE        specific TC-RNTI search space.    -   the C-RNTI for MSG4 is monitored in the common search and UE        specific C-RNTI search space.    -   The P-RNTI is monitored in the common search space.

DETAILS ON PREAMBLE FORMAT AND DETECTION

FIG. 5 shows the detailed timing of the basic random-access preamble,Format 0. The preamble is prefixed with a cyclic prefix (CP) to enablesimple frequency domain processing. Its length is in the order ofT_(GP)+T_(DS)=97.5+5 μs=102.5 μs, where T_(DS) corresponds to themaximum delay spread and T_(GP) corresponds to the maximum round triptime. The CP insures that the received signal is always circular afterremoving the CP in the random access receiver, and thus can be processedby FFTs (Fast Fourier transform). Therefore, the “active” random-accesspreamble duration is 1000 μs−2·T_(GP)−T_(DS)=800 μs. The RA subcarrierspacing is 1/800 μs=1250 Hz.

Formats 1, 2, 3 in FIG. 5 show the extended preamble formats. Format 1has an extended CP and is suited for cell radii up to approximately 100km. However, since no repetition occurs this format is only suited forenvironments with good propagation conditions. The approximate length ofthe CP and the preamble are indicated. Format 2 comprises a repeatedmain preamble and a CP of approximately 200 μs. With a random accessopportunity length of 2 ms the remaining guard period is alsoapproximately 200 μs. This format supports cell radii of up toapproximately 30 km. Format 3 also comprise a repeated main preamble andan extended CP. Using a RA opportunity length of 3 ms this formatsupports cell radii of up to approximately 100 km. The approximatelength of the CP and the repeated preamble are indicated. In opposite toformat 1 format 3 comprises a repeated preamble as shown and Format 3 istherefore better suited for environments with bad propagationconditions.

The requirements on the sequence comprising the preamble are two-fold:good auto-correlation function (ACF) properties and goodcross-correlation function (CCF) properties. A sequence that has ideal,i.e. periodic ACF and CCF properties is called the Zadoff-Chu sequence.The periodic ACF of Zadoff-Chu sequence is only non-zero at time-lagzero, and periodic extensions, and the magnitude of the CCF is equal tothe square-root of the sequence length, denoted here N. Due to specialproperties of Zadoff-Chu sequences, the number of sequences is maximizedif N is chosen prime. This together with the requirement that theeffective RA bandwidth N·1250 Hz should fit into 1.05 MHz leads toN=839.

A Zadoff-Chu sequence of length N may be expressed, in the frequencydomain, as Eq. 2:

$\begin{matrix}{{X_{ZC}^{(u)}(k)} = ^{{- {j\pi}}\; u\frac{k \cdot {({k + 1})}}{N}}} & \left( {{Eq}.\mspace{14mu} 2} \right)\end{matrix}$

where u is the index of the Zadoff-Chu sequence within the set ofZadoff-Chu sequences of length N.

Out of one Zadoff-Chu sequence—in the following also denoted rootsequence—multiple preamble sequences can be derived by cyclic shifting.Due to the ideal ACF of Zadoff-Chu sequence multiple mutually orthogonalsequences may be derived from a single root sequence by cyclic shiftingone root sequence multiple times the maximum allowed round trip timeplus delay spread in time-domain. The correlation of such a cyclicshifted sequence and the underlying root sequence has its peak no longerat zero but at the cyclic shift. If the received signal has now a validround trip delay—i.e. not larger than the maximum assumed round triptime—the correlation peak occurs at the cyclic shift plus the round tripdelay which is still in the correct correlation zone. This may be seenin FIG. 6.

FIG. 6 shows an example of a transmitted preamble that has a cyclicshift of 2T_(CS). As long as the round trip time is smaller than T_(CS)the correlation peak occurs in the correct zone. For small cells up to1.5 km radii all 64 preambles can be derived from a single root sequenceand are therefore orthogonal to each other. In larger cells not allpreambles can be derived from a single root sequence and multiple rootsequences must be allocated to a cell. Preambles derived from differentroot sequences are not orthogonal to each other. FIG. 6 also indicateslocation of the UE relative the eNB or Node B e.g. UE being close toNode B and UE located almost at cell border. The zones indicatingtransmitted sequences are enumerated 0, 1, 2, 3, 4 and 5 in FIG. 6. Asshown, in case the UE is close to the Node B, the time delay indicatinground trip delay is small. But in case the UE is located almost at cellborder, the time delay is large.

One disadvantage of Zadoff-Chu sequences is their behaviour at highfrequency offsets. A frequency-offset creates an additional correlationpeak in time-domain. A frequency offset has to be considered high if itbecomes substantial relative to the random RA sub-carrier spacing of1250 Hz, e.g. from 400 Hz upwards. The offset of the second correlationpeak relative to the main peak depends on the root sequence. An offsetsmaller than T_(CS) may lead to wrong timing estimates, whereas valueslarger than T_(CS) may increase the false alarm rate. In order to copewith this problem, LTE has a high-speed mode, or better high frequencyoffset mode, which disables certain cyclic shift values and rootsequences so that transmitted preamble and round trip time may uniquelybe identified. Additionally a special receiver combining bothcorrelation peaks is required. For cells larger than approximately 35 kmno set of 64 preambles exists that allows unique identification oftransmitted preamble and estimation of propagation delay, i.e. cellslarger than 35 km cannot be supported in high speed mode.

The random access preamble sequences are ordered according to aspecified table. The table is designed by first separating all PRACHsequences into two groups based on the quadrature phase shift keying(QPSK) cubic metric (CM) value using a fixed 1.2 dB threshold. Thesequences with low CM are more suitable to assign to large cells thanthe sequences with high CM. Within each CM-group, high and low, thesequences are further grouped according to the maximum allowed cyclicshift, S_(max,) at high speed.

There are however a limited number of possible preamble sequences, anddifferent sequences have better or worse properties in terms ofcoverage. For example, the sequences with good coverage properties arelimited. Due to the limitation of sequences, there is a need to reusethe preambles between cells. The network node receivers in two cellswhere UEs are using the same Zadoff-Chu sequences will detect preamblestransmitted in the other cell if they are received with sufficientstrength/power and if the same time/frequency resources are configuredfor PRACH. This problem may be referred to as “overhearing”. Overhearinghas negative impact on system performance and user experience.

SUMMARY

It is an object of embodiments herein to improve PRACH preambletransmission when using repeated PRACH occasions to enhance radiocoverage of the PRACH in a radio communications network and to avoidpreamble collisions

According to an aspect of embodiments herein, the object is achieved byproviding a method performed by a user equipment for performing preambletransmissions, on a random access channel, to a network node, the methodcomprising: determining a starting subframe for the preambletransmission(s) based on at least: a system frame number (SFN) receivedfrom the network node; a number of times (R) the preamble transmissionis to be repeated; and a random access channel configuration andtransmitting to the network node the preamble repeatedly starting in thedetermined starting subframe.

According to another aspect of embodiments herein, the object isachieved by providing a user equipment for performing preambletransmission, on a random access channel, to a network node, the userequipment being configured to: determine a starting subframe for thepreamble transmission(s) based on at least a SFN received from thenetwork node; a number of times the preamble transmission is to berepeated and a random access channel configuration, and the userequipment is further configured to transmit, to the network node, thepreamble repeatedly starting in the determined starting subframe

According to another aspect of embodiments herein, the object isachieved by providing a method performed by a network node for receivingpreamble transmission(s) from a user equipment on a random accesschannel, the method comprising: transmitting a SFN to the userequipment; transmitting a random access channel configuration to theuser equipment and receiving the preamble transmission repeatedlystarting in a starting subframe wherein the starting subframe isdetermined by the user equipment and the network node based on at leastthe SFN, the random access channel configuration, and a number of timesthe preamble transmission is to be repeated.

According to another aspect of embodiments herein, the object isachieved by means of a network node for receiving preambletransmission(s) from a user equipment on a random access channel, thenetwork node being configured to: transmit a SFN to the user equipment.The network node is further configured to transmit a random accesschannel configuration to the user equipment and to receive the preambletransmission repeatedly starting in a starting subframe wherein thestarting subframe is determined by the user equipment and the networknode based on at least the SFN, the random access channel configuration,and a number of times the preamble transmission is to be repeated.

An advantage achieved by embodiments herein is to avoid preamblecollisions since a defined starting point for each repeated PRACHpreamble transmission is determined. Both the user equipment and thenetwork determine the starting point and hence know when a repeatedpreamble transmission by the user equipment is to occur.

Another advantage achieved by embodiments herein is that systemperformance and user experience are improved since overhearing ofrepeated PRACH preamble transmissions in other (neighbouring) cells isreduced.

Yes another advantage achieved is that by introducing means to determinethe start subframe, and implicitly the end subframe, of the repeatedPRACH transmission of the user equipment, the network node complexityand PRACH false alarm probability may be reduced.

BRIEF DESCRIPTION OF THE DRAWINGS

Embodiments will now be described in more detail in relation to theenclosed drawings. The figures are schematic and simplified for clarity,and they merely show details which are essential for the understandingof the embodiments presented herein, while other details have been leftout. Throughout the drawings, the same reference numerals are used foridentical or corresponding parts.

FIG. 1 shows a simplified example of a random-access-preambletransmission.

FIG. 2 illustrates signalling messages over the air interface forcontention-based random access procedure in LTE.

FIG. 3 illustrates a network scenario wherein contention between two UEsoccurs during a contention-based random access.

FIG. 4 illustrates an example of signalling messages over the airinterface for contention-free random access procedure in LTE.

FIG. 5 show random access preambles for different formats 0-3 as definedby 3GPP.

FIG. 6 shows graphs depicting correlation vs time when a UE, based onits location in a cell, transmits preamble(s) or sequences.

FIG. 7 depicts a radio communications network in which embodimentsherein may be implemented.

FIG. 8 shows a method performed by a UE for preamble transmissions to anetwork node in accordance with embodiments herein.

FIG. 9 shows a method performed by a UE for enabling preambletransmissions from a UE in accordance with exemplary embodiments herein.

FIG. 10 shows a method performed by a network node for receivingpreamble transmission from a UE in accordance with herein.

FIG. 11 is a schematic block diagram of a UE according to an exemplaryembodiment herein.

FIG. 12 is a schematic block diagram of a network node according to anexemplary embodiment herein.

DETAILED DESCRIPTION

FIG. 7 depicts a radio communications network 100 in which embodimentsherein may be implemented. In some embodiments, the radio communicationsnetwork 100 may be a wireless communications network such as a LTE,LTE-Advanced, (WCDMA), Global System for Mobile communications/EnhancedData rate for GSM Evolution (GSM/EDGE), Worldwide Interoperability forMicrowave Access (WiMax), Ultra Mobile Broadband (UMB) or GSM, or anyother similar cellular network or system. The radio communicationnetwork 100 is exemplified herein as an LTE network.

The radio communications network 100 comprises a network node 110. Thenetwork node 110 serves at least one cell 115. The network node 110 maye.g. be a base station, a radio base station, eNB, eNodeB, a Home NodeB, a Home eNode B, femto Base Station (BS), pico BS or any other networkunit capable of communicating with a user equipment within the cellserved by the network node depending e.g. on the radio access technologyand terminology used. The network node 110 may also be e.g. a basestation controller, a network controller, a relay node, a repeater, anaccess point, a radio access point, a Remote Radio Unit (RRU) or aRemote Radio Head (RRH).

A cell is a geographical area where radio coverage is provided by radiobase station equipment at a base station site or at remote locations inRemote Radio Units (RRU). The cell definition may also incorporatefrequency bands and radio access technology used for transmissions,which means that two different cells may cover the same geographicalarea but using different frequency bands. Each cell is identified by anidentity within the local radio area, which is broadcast in the cell.Another identity identifying the cell 115 uniquely in the whole radiocommunication network 100 is also broadcasted in the cell 115. Thenetwork node 110 communicates over the air or radio interface operatingon radio frequencies with the UEs within range of the network node 110.

In FIG. 7, a user equipment 121 is shown located within the cell 115.The UE 121 is configured to communicate within the radio communicationsnetwork 100 via the network node 110 over a radio link 131 when presentin the cell 115 served by the network node 110. The UE 121 may e.g. beany kind of wireless device such as a mobile phone, a cellular phone, aPersonal Digital Assistant (PDA), a smart phone, a tablet, a sensorequipped with a UE, Laptop Mounted Equipment (LME) (e.g. USB), LaptopEmbedded Equipment (LEE), Machine Type Communication (MTC) device, orMachine to Machine (M2M) device, Customer Premises Equipment (CPE), etc.

As previously described, when a UE needs to contact the network withouthaving a dedicated resource in the UL a random access procedure isavailable as a means to request UL grant. The UE performs preamble orsequence transmissions, on a physical PRACH for that purpose.

In order to reduce cost and enhanced coverage for certain UEs orterminals in LTE, i.e. MTC devices, it has been concluded that the PRACHchannel coverage needs to be enhanced. The enhancement will at leastpartially be realized with repetition. It has been agreed to reuse theexisting formats and configurations described previously and in thespecification 3GPP TS 36.211, but with repetition over multiple timeoccasions.

The repeated resource may either use the same resource configuration aslegacy UEs, with a separation in the preamble sequences used, or theremay also be additional resources configured for repetition. A number ofdifferent repetition levels may be supported. The repetition level touse in what condition is not fully settled. The configuration of RACHresources may be done using one of the existing system informationblocks (SIBs), e.g. SIB2 or in a new SIB.

A network node, e.g. eNB or base station, may combine the transmissionsin multiple PRACH occasions to accumulate energy and improve detectionof the transmission.

As discussed in the background section above, there are a limited numberof possible preamble sequences, and different sequences have better orworse properties in terms of coverage. Especially the sequences withgood coverage properties are limited. Due to the limitation ofsequences, there is a need to reuse the preambles between cells. The eNBreceivers in two cells where UEs are using the same Zadoff-Chu sequenceswill detect preambles transmitted in the other cell if they are receivedwith sufficient strength and if the same time/frequency resources areconfigured for PRACH causing “overhearing”.

It should be noted that problems with “overhearing” is not significantfor normal preamble transmissions, i.e. for legacy or normal UEs, sincethere are quite many possible root sequences for a UE to select from andtherefore “overhearing” may be avoided by proper preamble allocationreuse planning. Moreover, power control is applied and the probabilityof a preamble being detected in a different cell than the target cell,but configured with the same set of random access preambles, is low.However, for enhanced coverage with repetition as described above, thepower control may become very crude and less accurate.

As part of the developing of the embodiments described herein, it hasbeen noted that the detection of repeated preamble transmission with lownetwork complexity and low false alarm probability may be facilitated ifthe UE and the network node apply the same start subframe, and thus endsubframe, for the repeated preambles. However, currently there are nomeans for the UE and network node to determine the start subframe, andthus end subframe.

In short, the embodiments described hereinafter address these issues bydefining a starting point for each repeated PRACH preamble transmissionwhich is known to both UE and network node. In some embodiments, thestarting point may be defined as a function of the system frame number,the preamble repetition level and the PRACH resource configuration. Thismeans that separate starting subframes may be applied in thecorresponding cells to expand the domain of reuse between cellsemploying PRACH repetition over multiple PRACH occasions.

In some embodiments, the starting frame offset may be configured bysignaling. One example of the signaling is dedicated signaling, so thatindividual UEs in the cell may be configured with a starting subframedepending on which other cell it is interfering the most with. Accordingto another example, the configuration may be broadcasted by the networknode. In some embodiments, the control signaling may be implicit, and bederived by the UE from already existing signaling, e.g. by using thecell-ID. The amount of energy received from neighbor cells using thesame root sequence may then be reduced.

Before describing different exemplary embodiments, the main stepsperformed by a UE 121 for performing preamble transmission(s), on arandom access channel (PRACH), to a network node 110 are presented inrelation to FIG. 8.

In action 801, the method comprises, determining a starting subframe forthe preamble transmission(s) based on at least: a system frame number(SFN) received from the network node 110; a number of times (R) thepreamble transmission(s) is to be repeated; and a random access channelconfiguration.

In action 802, the method further comprises, transmitting, to thenetwork node 110, the preamble repeatedly starting in the determinedstarting subframe.

The determined starting subframe may therefore be viewed as a functionof the SFN; the preamble repetition level i.e. the number of times R,and the PRACH resource configuration. According to an embodiment, thedetermined starting subframe is further determined based on a firstoffset being dependent on the PRACH configuration. The preamblerepetition level may also be denoted a bundle size (in number ofrepeated PRACH occasions).

It should be noted that a PRACH occasion may span more than one subframeand that the starting subframe referred to herein targets or refers tothe subframe where the PRACH occasions starts.

In some embodiments, the SFN is given by the master information block(MIB) transmitted on the physical broadcast channel (PBCH) by thenetwork node 110 and the time periodicity of PRACH occasion is given bythe PRACH configuration in a SIB e.g. in SIB2 or in a new dedicated SIB.

A PRACH occasion is the occasion to transmit one PRACH format, i.e.format 0, 1, 2, 3 or 4. It should be mentioned that a number of PRACHconfigurations are available in the specification 3GPP TS 36.211 withdifferent PRACH occasion frequencies. For example, according to thecurrent specification, the PRACH resources may be configured with afrequency ranging from every millisecond (ms), i.e. each subframe, downto once per 20 ms, i.e. once every other radio frame.

If N represents the average number of subframes comprising at least onePRACH resource in a 10-ms period and n_(i) (e.g. N may in currentspecification take values between 0.5 and 10 dependent onconfigurations; i=0, . . . N_(SFN)−1) the occasion in the SFN, R therepetition level or bundle size, the starting occasion or subframe may,for example, be given by any SFN and i fulfilling:

0=((SFN+T)·N+i) mod R   (Eq. 3)

-   -   mod being a modulo operation; T is here a first offset dependent        on the PRACH configuration, where for example T=1 if PRACH only        is available in odd subframes, else T=0. This means that the        start subframe is SFN+i, e.g. all SFN and i fulfilling the        equation are possible starting subframes.

For example, when having 2 PRACH occasions in a radio frame, e.g. insubframe #1 and subframe #6, and a PRACH bundling of 3, this may resultin a starting in subframe #1 in even SFNs and subframe #6 in odd SFNs,e.g. subframe #1, #16, #31, etc.

In Equation 3, i is a subframe or starting occasion, comprising radioresources configured for the random access channel in frame SFN, wherein1=0, . . . ,N_(SFN)−1;

As mentioned above, T is the first offset and is dependent on the randomaccess channel configuration and takes value T=1 if radio resourcesconfigured for the random access channel are available in onlyodd-number subframes, otherwise T=0;

N_(SFN) is the number of subframes comprising at least one random accesschannel resource in frame with SFN; and N is the average number ofsubframes comprising at least one random access channel resource;

T, N and N_(SFN) being derived from the random access channelconfiguration provided by the network or provided by the network node tothe UE in the random access channel configuration.

According to an embodiment, the starting subframe may be determinedbased on a second offset being a cell identifier such as a physical cellidentity (PCI), received by the UE during synchronization with thenetwork node, or the second offset is a cell identity received in a SIBor determined by the UE based on a physical-layer cell identity. Forexample, the starting subframe of a repeated bundled PRACH transmissionmay be offset by a cell specific value K which is here the secondoffset. For example, it could be based on, or associated to, the PCIsignalled by the synchronization signals from the network node uponsynchronization with the cell.

For example, in E-UTRAN, there are 504 unique physical-layer cellidentities. The physical-layer cell identities are grouped into 168unique physical-layer cell-identity groups, each group containing threeunique identities. The grouping is such that each physical-layer cellidentity is part of one and only one physical-layer cell-identity group.A physical-layer cell identity N_(ID) ^(cell)=3N_(ID) ⁽¹⁾+N_(ID) ⁽²⁾ isthus uniquely defined by a number N_(ID) ⁽¹⁾ in the range of 0 to 167,representing the physical-layer cell-identity group, and a number N_(ID)⁽²⁾ in the range of 0 to 2, representing the physical-layer identitywithin the physical-layer cell-identity group.

Hence, K may be determined by the UE 121 based on either N_(ID) ^(cell),N_(ID) ⁽¹⁾ or N_(ID) ⁽²⁾.

As mentioned above, the second offset K may be received in SIB ordetermined by the UE based on the physical-layer cell identity. Forexample K could be related to the cell identity signaled in SIB1, forexample the 28 bit cell identifier in SIB1 or parts of the same. The UE121 may derive K from the first 20 bits identifying the network node 110or the last 8 bits identifying the cell served by the network node 110.

In some embodiments, K may also be a new parameter value signalled forthis purpose (dedicated). This may, for example, be performed in SIB2 orin a new dedicated SIB.

When both the first offset value T and second offset value K are used, astarting subframe or starting occasion is determined for a frame withSFN as any subframe i fulfilling:

0=((SFN+T)·N+i+K) mod R   (Eq. 4)

Similarly to Equation 3, i in Equation 4 represents a subframe orstarting occasion comprising radio resources configured for the randomaccess channel in a frame SFN, wherein i=0, . . . , N_(SFN)−1;

T is the first offset dependent on the random access channelconfiguration and takes value T=1 if radio resources configured for therandom access channel are available in only odd-number subframes,otherwise T=0;

N_(SFN) is the number of subframes comprising at least one random accesschannel resource in frame with SFN;

N is the average number of subframes comprising at least one randomaccess channel resource;

According to another embodiment, the starting subframe may be determinedbased on a preamble sequence dependent offset. For example, the startingsubframe of a bundled PRACH transmission may be offset by a PRACHsequence specific value in order to further reduce the potentialoverhearing between different PRACH sequences within the same cell. Forexample, the offset value is based on a function of the index of therandom access sequence (PRACH sequence). This would also help inreducing PRACH latency. According to an embodiment, the preamblesequence dependent offset may also be a function of the number of timesthe preamble transmission is to be repeated (R) i.e. the preamblerepetition level in order to evenly distribute starting subframes orstarting occasions.

After determining the starting subframe, the UE 121 is configured totransmit a preamble repeatedly starting in the determined startingsubframe.

Referring to FIG. 9, there is illustrated a flowchart depictingexemplary embodiments of a procedure performed by a UE.

As shown, in action 900 a, a UE initiates a random access procedure. Aspreviously described, upon initiating the random access procedure, theUE randomly selects one of the available preambles for contention-basedrandom access.

In action 901 and in accordance with the previously describedembodiments, the UE determines when to transmit the selected preamble,i.e. the UE determines a starting subframe for the preambletransmission(s). For this purpose and as shown in 901 a, the UEdetermines a SFN and PRACH configuration(s);

In 901 b, the UE determines which PRACH repetition factor R to use andin 901 c, the UE determines a next valid PRACH start occasion.

In 902 a, the UE initiate PRACH transmission in next valid subframe i.e.transmits the preamble repeatedly starting in the determined startingsubframe.

In case of time division duplex (TDD), certain configurations enablemore than one PRACH opportunity per subframe, but in different frequencybands. Thereby, for TDD, the starting position not only relates to astarting point in time, but possibly also in frequency. With thepossibility to consider opportunities in time and frequency domain incombination, it is possible to define opportunity patterns. Such apattern could be cyclic over the frequency domain random accessopportunities, and be defined by a starting point in time and infrequency.

Below is illustrated a plausible time-frequency pattern with threedifferent possible starting points in the frequency domain, 1, 2 and 3.In the example, the time frequency opportunity pattern is defined by astarting point in time and in frequency.

3 2 1 3 2 1 3 2 1 3 2 1

It should be mentioned that in traditional random access in LTE, the UEobtains a temporary identifier RA-RNTI that is associated to theselected random access opportunity. With repetitive random accesspreambles, there may be different options how to select the RA-RNTI. Incurrent LTE, it is selected as:

RA-RNTI=1+t _(—) id+10*f _(—) id

-   -   where t_id is the index of the first subframe of the specified        PRACH (0≦t_id<10), and f_id is the index of the specified PRACH        within that subframe, in ascending order of frequency domain        (0≦f_id<6).

However, given the long foreseen repetitions, it may be more attractiveto instead consider the index of the last subframe.

As previously described, the UE may receive one or two offset valuesfrom the network node through configuration enabling the UE to determinethe starting subframe.

The network node may configure the offset value(s) for a current cell ofthe UE to be used in determining a starting subframe for the preambletransmissions of the UE.

The network node may aggregate statistics over random access (RA)performance, i.e. monitoring the RA. This means that the network nodemay obtain certain performance indicators. One example of such aperformance indicator is the number of received preambles over a timewindow. This may be aggregated by the network node in e.g. a counter.Another example of such a performance indicator is the number ofrequired preamble repetitions before the preamble was detected. This maybe aggregated by the network node in e.g. a histogram counter. Thehistogram counter may comprise multiple counters, one for each bin ofdata, for example, four counters corresponding to 0,1,2,3 repetitions. Afurther example of such a performance indicator is the number ofoverheard preambles over a time window. Here, the network node mayassume that all received preambles that have not lead to completed RAare due to overhearing.

The statistics may be aggregated over determined time periods in thenetwork node and may be reported regularly by the network node to anetwork management node. This may also be reported by the network nodeon demand, or when a pre-configured or configurable criterion is met inthe network node. The latter may also be considered or referred to as analarm. One example of such a configurable criterion is when the numberof overheard preambles over a time period exceeds a determinedthreshold.

As previously described in order to facilitate network node complexityand avoid preamble collisions a defined starting subframe for eachrepeated PRACH preamble transmission needs to be defined and known notonly to the UE but also to the network node or eNB.

FIG. 10 illustrates a method performed by the network node 110 forreceiving preamble transmissions from the UE 121 on the PRACH.

As shown, the main steps performed by the network node 110 comprise:

(1001) transmitting a SFN and a random access channel configuration tothe UE 121; and

(1002) receiving the preamble transmission repeatedly starting in astarting subframe wherein the starting subframe is determined by the UE121 and the network 20 node 110 based on at least on the SFN, the randomaccess channel configuration and a number of times (R) the preambletransmission is to be repeated.

Similarly to the actions performed by the UE 121, the network node 110determines the starting subframe based on a first offset T beingdependent on the random access channel configuration. As previouslydescribed, the starting subframe is determined for a frame with SFN asany subframe i fulfilling equation 3 presented before which is repeatedhere.

0=((SFN+T)·N+i) mod R

-   -   wherein,    -   i is a subframe comprising radio resources configured for the        random access channel in frame SFN, wherein i=0, . . .        ,N_(SFN)−1;    -   T is the first offset dependent on the random access channel        configuration and takes value T=1 if radio resources configured        for the random access channel are available in only odd-number        subframes, otherwise T=0;    -   N_(SFN) is the number of subframes comprising at least one        random access channel resource in frame with SFN;    -   N is the average number of subframes comprising at least one        random access channel resource;    -   T, N and N_(SFN) being derived from the random access channel        configuration provided by the network node to the UE; and    -   mod is the modulo operation.

According to an embodiment, the network node may determine the startingbased on a second offset K being a cell identifier such as, a physicalcell identity, PCI, transmitted to the UE during synchronization withthe UE or the second offset is a cell identity transmitted in a systeminformation block to the UE.

The starting subframe may further be determined based on a preamblesequence dependent offset; wherein the preamble sequence dependentoffset is a function of a number of available preambles for the numberof times the preamble transmission is to be repeated, or the preamblesequence dependent offset is a function of a physical random accesschannel sequence index.

When both the first offset value T and the second offset value K areused, the network node determines the starting subframe for a frame withSFN as any subframe i fulfilling equation 4 presented before which isrepeated below:

0=((SFN+T)·N+i+K) mod R

-   -   wherein,    -   i is a subframe comprising radio resources configured for the        random access channel in a frame SFN, wherein i=0, . . . ,        N_(SFN)−1;    -   T is a first offset dependent on the random access channel        configuration and takes value T=1 if radio resources configured        for the random access channel are available in only odd-number        subframes, otherwise T=0;    -   N_(SFN) is the number of subframes comprising at least one        random access channel resource in frame with SFN;    -   N is the average number of subframes comprising at least one        random access channel resource;    -   T, N and N_(SFN) being derived from the random access channel        configuration provided by the network node to the UE;    -   K is the second offset,

Several advantages are achieved by embodiments described herein. Anadvantage is to avoid preamble collisions since a defined starting pointfor each repeated PRACH preamble transmission is determined. Both the UEand the network determine the starting point and hence know when arepeated preamble transmission by the user equipment is to occur.

Another advantage achieved by embodiments herein is that systemperformance and user experience are improved since overhearing ofrepeated PRACH preamble transmissions in other (neighbouring) cells isreduced.

Yes another advantage achieved is that by introducing means to determinethe start subframe, and implicitly the end subframe, of the repeatedPRACH transmission of the UE, the network node complexity and PRACHfalse alarm probability may be reduced.

To perform the method actions described earlier, a UE 121 and a networknode 110 are provided in accordance with FIGS. 11-12.

FIGS. 11-12 are schematic block diagrams of embodiments of the UE 121and the network node 110. The UE 121 is configured to perform themethods related to the UE according to embodiments described before. Thenetwork node 110 is also configured to perform the methods related tonetwork node according to embodiments described above.

The embodiments for performing preamble transmissions on a random accesschannel to a network node 110 in a radio communication network 100,wherein the preamble transmission is repeated one or more times in radioresources configured for the random access channel, may be implementedthrough one or more processors 1110 in the UE 121 depicted in FIG. 11,together with computer program code for performing the functions and/ormethod actions of the embodiments herein. The program code mentionedabove may also be provided as a computer program product, for instancein the form of a data carrier carrying computer program code forperforming embodiments herein when being loaded into the UE 121. Onesuch carrier may be in the form of a CD ROM disc. It is however feasiblewith other data carriers such as a memory stick. The computer programcode may furthermore be provided as pure program code on a server anddownloaded to the UE 121.

The UE 121 further comprises a transmitter TX and a receiver RX, or atransceiver 1120, over which the UE 121 may transmit/receivetransmissions and information from the network node 110. The UE 121further comprises a memory 1130. The memory 1130 may, for example, beused to store information, either configured in the UE 121 and/orreceived from the network node 110, to perform the methods describedherein, etc.

The embodiments for enabling preamble reception on a random accesschannel from a UE 121 in a radio communication network 100, wherein thereception of the preamble transmission is repeated one or more times inradio resources configured for the random access channel, may beimplemented through one or more processors 1210 in the network node 110depicted in FIG. 12, together with computer program code for performingthe functions and/or method actions of the embodiments herein. Theprogram code mentioned above may also be provided as a computer programproduct, for instance in the form of a data carrier carrying computerprogram code for performing embodiments herein when being loaded intothe network node 110. One such carrier may be in the form of a CD ROMdisc. It is however feasible with other data carriers such as a memorystick. The computer program code may furthermore be provided as pureprogram code on a server and downloaded to the network node 110.

The network node 110 comprises a transmitter TX and a receiver RX, or atransceiver 1220, over which the network node 110 may transmit/receivetransmissions and information from the UE 121. The network node 110further comprises a memory 1230. The memory 1130 may, for example, beused to store offset values and other information for performing themethods described herein, etc. The network node 110 may also comprise aninput/output interface 1240, which may be used to communicate with otherradio network entities or network nodes in a core network.

As will be readily understood by those familiar with communicationsdesign, that functions from other circuits may be implemented usingdigital logic and/or one or more microcontrollers, microprocessors, orother digital hardware. In some embodiments, several or all of thevarious functions may be implemented together, such as in a singleapplication-specific integrated circuit (ASIC), or in two or moreseparate devices with appropriate hardware and/or software interfacesbetween them. Several of the functions may be implemented on a processorshared with other functional components of a wireless terminal ornetwork node, for example.

Alternatively, several of the functional elements of processing circuitsdiscussed may be provided through the use of dedicated hardware, whileothers are provided with hardware for executing software, in associationwith the appropriate software or firmware. Thus, the term “processor” or“controller” as used herein does not exclusively refer to hardwarecapable of executing software and may implicitly include, withoutlimitation, digital signal processor (DSP) hardware, read-only memory(ROM) for storing software, random-access memory for storing softwareand/or program or application data, and non-volatile memory. Otherhardware, conventional and/or custom, may also be included. Designers ofcommunications receivers will appreciate the cost, performance, andmaintenance trade-offs inherent in these design choices. The differentactions taken by the different nodes may be implemented with differentcircuits.

It should be noted that although terminology from 3GPP LTE has been usedherein in order to exemplify some of the embodiments, this should not beseen as limiting to only the aforementioned system. As previouslymentioned, other wireless systems, including WCDMA, WiMax, UMB and GSM,may also benefit from exploiting the ideas covered by the embodimentsdescribed herein.

Also note that terminology such as eNodeB and UE should be considerednon-limiting and does in particular not imply a certain hierarchicalrelation between the two; in general “eNodeB” could be considered asfirst device or node and “UE” as a second device or node, and these twodevices or nodes communicate with each other over some radio channel.

As used herein, the term “and/or” comprises any and all combinations ofone or more of the associated listed items.

Further, as used herein, the common abbreviation “e.g.”, which derivesfrom the Latin phrase “exempli gratia,” may be used to introduce orspecify a general example or examples of a previously mentioned item,and is not intended to be limiting of such item. If used herein, thecommon abbreviation “i.e.”, which derives from the Latin phrase “idest,” may be used to specify a particular item from a more generalrecitation. The common abbreviation “etc.”, which derives from the Latinexpression “et cetera” meaning “and other things” or “and so on” mayhave been used herein to indicate that further features, similar to theones that have just been enumerated, exist.

As used herein, the singular forms “a”, “an” and “the” are intended tocomprise also the plural forms as well, unless expressly statedotherwise. It will be further understood that the terms “includes,”“comprises,” “including” and/or “comprising,” when used in thisspecification, specify the presence of stated features, actions,integers, steps, operations, elements, and/or components, but do notpreclude the presence or addition of one or more other features,actions, integers, steps, operations, elements, components, and/orgroups thereof.

Unless otherwise defined, all terms comprising technical and scientificterms used herein have the same meaning as commonly understood by one ofordinary skill in the art to which the described embodiments belongs. Itwill be further understood that terms, such as those defined in commonlyused dictionaries, should be interpreted as having a meaning that isconsistent with their meaning in the context of the relevant art andwill not be interpreted in an idealized or overly formal sense unlessexpressly so defined herein.

The embodiments herein are not limited to the above described preferredembodiments. Various alternatives, modifications and equivalents may beused. Therefore, the above embodiments should not be construed aslimiting.

1. A method performed by a user equipment, UE, for performing preambletransmissions, on a random access channel, to a network node, the methodcomprising: determining a starting subframe for the preambletransmission(s) based on at least: a system frame number, SFN, receivedfrom the network node; a number of times, R, the preamble transmissionis to be repeated; a random access channel configuration andtransmitting, to the network node, the preamble repeatedly starting inthe determined starting subframe.
 2. The method according to claim 1wherein determining the starting subframe based on the random accesschannel configuration comprises determining the starting subframe basedon a first offset being dependent on the random access channelconfiguration.
 3. The method according to claim 1 wherein determiningfurther comprising determining the starting subframe based on a secondoffset being a cell identifier such as, a physical cell identity, PCI,received during synchronization with the network node, or the secondoffset is a cell identity received in a system information block fromthe network, or the second offset is determined by the UE based on aphysical-layer cell identity.
 4. The method according to anyone of claim1 wherein determining further comprising determining the startingsubframe based on a preamble sequence dependent offset; wherein thepreamble sequence dependent offset is a function of a number ofavailable preambles for the number of times the preamble transmission isto be repeated, or the preamble sequence dependent offset is a functionof a physical random access channel sequence index.
 5. The methodaccording to claim 2 comprising determining the starting subframe for aframe with SFN as any subframe i fulfilling:0=((SFN+T)·N+i) mod R wherein, i is a subframe comprising radioresources configured for the random access channel in frame SFN, whereini=0, . . . ,NSFN−1; T is the first offset dependent on the random accesschannel configuration and takes value T=1 if radio resources configuredfor the random access channel are available in only odd-numbersubframes, otherwise T=0; NSFN is the number of subframes comprising atleast one random access channel resource in frame with SFN; N is theaverage number of subframes comprising at least one random accesschannel resource; T, N and NSFN being derived from the random accesschannel configuration provided by the network; and mod is a modulooperation.
 6. The method according to claim 3 comprising determining thestarting subframe for a frame with SFN as any subframe i fulfilling:0=((SFN+T)·N+i+K) mod R wherein, i is a subframe comprising radioresources configured for the random access channel in a frame SFN,wherein i=0, . . . , NSFN−1; T is a first offset dependent on the randomaccess channel configuration and takes value T=1 if radio resourcesconfigured for the random access channel are available in onlyodd-number subframes, otherwise T=0; NSFN is the number of subframescomprising at least one random access channel resource in frame withSFN; N is the average number of subframes comprising at least one randomaccess channel resource; T, N and NSFN being derived from the randomaccess channel configuration provided by the network; K is the secondoffset, and mod is a modulo operation.
 7. A user equipment, forperforming preamble transmissions, on a random access channel, to anetwork node, the user equipment being configured to: determine astarting subframe for the preamble transmission(s) based on at least: asystem frame number, SFN, received from the network node; a number oftimes, R, the preamble transmission is to be repeated; a random accesschannel configuration and transmit, to the network node, the preamblerepeatedly starting in the determined starting subframe.
 8. The userequipment according to claim 7 is configured to determine the startingsubframe based on a first offset being dependent on the random accesschannel configuration.
 9. The user equipment according to claim 7 isconfigured to determine the starting subframe based on a second offsetbeing a cell identifier such as, a physical cell identity, PCI, receivedduring synchronization with the network node, or the second offset is acell identity received in a system information block from the networknode, or the second offset is determined by the user equipment based ona physical-layer cell identity.
 10. The user equipment according toclaim 7 is configured to determine the starting subframe based on apreamble sequence dependent offset; wherein the preamble sequencedependent offset is a function of a number of available preambles forthe number of times the preamble transmission is to be repeated, or thepreamble sequence dependent offset is a function of a physical randomaccess channel sequence index.
 11. The user equipment according to claim8 is configured to determine the starting subframe for a frame with SFNas any subframe i fulfilling:0=((SFN+T)·N+i)mod R wherein, i is a subframe comprising radio resourcesconfigured for the random access channel in frame SFN, wherein i=0, . .. ,NSFN−1; T is the first offset dependent on the random access channelconfiguration and takes value T=1 if radio resources configured for therandom access channel are available in only odd-number subframes,otherwise T=0; NSFN is the number of subframes comprising at least onerandom access channel resource in frame with SFN; N is the averagenumber of subframes comprising at least one random access channelresource; T, N and NSFN being derived from the random access channelconfiguration provided by the network; and mod is a modulo operation.12. The user equipment according to claim 9 is configured to determinethe starting subframe for a frame with SFN as any subframe i fulfilling:0=((SFN+T)·N+i+K)mod R wherein, i is a subframe comprising radioresources configured for the random access channel in a frame SFN,wherein i=0, . . . , NSFN−1; T is a first offset dependent on the randomaccess channel configuration and takes value T=1 if radio resourcesconfigured for the random access channel are available in onlyodd-number subframes, otherwise T=0; NSFN is the number of subframescomprising at least one random access channel resource in frame withSFN; N is the average number of subframes comprising at least one randomaccess channel resource; T, N and NSFN being derived from the randomaccess channel configuration provided by the network; K is the secondoffset, and mod is a modulo operation.
 13. A method performed by anetwork node for receiving preamble transmission(s) from a userequipment, UE, on a random access channel, the method comprising:transmitting a system frame number, SFN, to the UE and a random accesschannel configuration to the UE; and receiving the preamble transmissionrepeatedly starting in a starting subframe wherein the starting subframeis determined by the UE and the network node based on at least the SFN,the random access channel configuration, and a number of times, R, thepreamble transmission is to be repeated.
 14. The method according toclaim 13 wherein the starting subframe is determined based on a firstoffset being dependent on the random access channel configuration. 15.The method according to claim 13 wherein the starting subframe isdetermined based on a second offset being a cell identifier such as, aphysical cell identity, PCI, transmitted to the UE duringsynchronization with the UE, or the second offset is a cell identitytransmitted in a system information block to the UE.
 16. The methodaccording to claim 15 wherein the starting subframe is determined basedon a preamble sequence dependent offset; wherein the preamble sequencedependent offset is a function of a number of available preambles forthe number of times the preamble transmission is to be repeated, or thepreamble sequence dependent offset is a function of a physical randomaccess channel sequence index.
 17. The method according to claim 14wherein the starting subframe is determined for a frame with SFN as anysubframe i fulfilling:0=((SFN+T)·N+i) mod R wherein, i is a subframe comprising radioresources configured for the random access channel in frame SFN, whereini=0, . . . ,NSFN−1; T is the first offset dependent on the random accesschannel configuration and takes value T=1 if radio resources configuredfor the random access channel are available in only odd-numbersubframes, otherwise T=0; NSFN is the number of subframes comprising atleast one random access channel resource in frame with SFN; N is theaverage number of subframes comprising at least one random accesschannel resource; T, N and NSFN being derived from the random accesschannel configuration provided by the network node to the UE; and mod isa modulo operation.
 18. The method according to claim 15 wherein thestarting subframe is determined for a frame with SFN as any subframe ifulfilling:0=((SFN+T)·N+i+K) mod R wherein, i is a subframe comprising radioresources configured for the random access channel in a frame SFN,wherein i=0, . . . , N_(SFN)−1; T is a first offset dependent on therandom access channel configuration and takes value T=1 if radioresources configured for the random access channel are available in onlyodd-number subframes, otherwise T=0; NSFN is the number of subframescomprising at least one random access channel resource in frame withSFN; N is the average number of subframes comprising at least one randomaccess channel resource; T, N and NSFN being derived from the randomaccess channel configuration provided by the network node to the UE; Kis the second offset, and mod is a modulo operation.
 19. A network nodefor receiving preamble transmission(s) from a user equipment, UE, on arandom access channel, the network node being configured to: transmit asystem frame number, SFN, to the UE and a random access channelconfiguration to the UE, receive the preamble transmission repeatedlystarting in a starting subframe wherein the starting subframe isdetermined by the UE and the network based on the SFN, the random accesschannel configuration, the offset value and a number of times, R, thepreamble transmission is to be repeated.
 20. The network node accordingto claim 19 wherein the starting subframe is determined based on a firstoffset being dependent on the random access channel configuration. 21.The network node according to claim 19 wherein the starting subframe isdetermined based on a second offset being a cell identifier such as, aphysical cell identity, PCI, transmitted to the UE duringsynchronization with the UE, or the second offset is a cell identitytransmitted in a system information block to the UE.
 22. The networknode according to anyone of claims 19 claim 19 wherein the startingsubframe is determined based on a preamble sequence dependent offset;wherein the preamble sequence dependent offset is a function of a numberof available preambles for the number of times the preamble transmissionis to be repeated, or the preamble sequence dependent offset is afunction of a physical random access channel sequence index.
 23. Thenetwork node according to claim 20 wherein the starting subframe isdetermined for a frame with SFN as any subframe i fulfilling:0=((SFN+T)·N+i) modR wherein, i is a subframe comprising radio resourcesconfigured for the random access channel in frame SFN, wherein i=0, . .. ,NSFN−1; T is the first offset dependent on the random access channelconfiguration and takes value T=1 if radio resources configured for therandom access channel are available in only odd-number subframes,otherwise T=0; NSFN is the number of subframes comprising at least onerandom access channel resource in frame with SFN; N is the averagenumber of subframes comprising at least one random access channelresource; T, N and NSFN being derived from the random access channelconfiguration provided by the network node to the UE; and mod is amodulo operation.
 24. The network node according to claim 21 wherein thestarting subframe is determined for a frame with SFN as any subframe i0=((SFN+T)·N+i+K)mod R wherein, i is a subframe comprising radioresources configured for the random access channel in a frame SFN,wherein i=0, . . . , NSFN−1; T is a first offset dependent on the randomaccess channel configuration and takes value T=1 if radio resourcesconfigured for the random access channel are available in onlyodd-number subframes, otherwise T=0; NSFN is the number of subframescomprising at least one random access channel resource in frame withSFN; N is the average number of subframes comprising at least one randomaccess channel resource; T, N and NSFN being derived from the randomaccess channel configuration provided by the network node to the UE; Kis the second offset, and mod is a modulo operation.